New Types of Reactivity of α,β‐Unsaturated N,N‐Dimethylhydrazones: Chemodivergent Diastereoselective Synthesis of Functionalized Tetrahydroquinolines and Hexahydropyrrolo[3,2‐b]indoles

The indium trichloride‐catalyzed reaction between aromatic imines and α,β‐unsaturated N,N‐dimethylhydrazones in acetonitrile afforded 1,2,3,4‐tetrahydroquinolines bearing a hydrazone function at C4 through a one‐pot diastereoselective domino process that involves the formation of two C? C bonds and the controlled generation of two stereocenters, one of which is quaternary. This reaction constitutes the first example of an α,β‐unsaturated dimethylhydrazone that behaves as a dienophile in a hetero Diels–Alder reaction. The related reaction between anilines, aromatic aldehydes, and methacrolein dimethylhydrazone in CHCl₃ with BF₃?Et₂O as catalyst afforded polysubstituted 1,2,3,3a,4,8b‐hexahydropyrrolo[3,2‐b]indoles as major products through a fully diastereoselective ABB′C four‐component domino process that generates two cycles, three stereocenters, two C? C bonds, and two C? N bonds in a single operation.     

Fe3O4@SiO2-CeCl3 Catalyzed Chemoselective Synthesis of Functionalized 3-Substituted-1,5-Benzodiazepines via One-pot Multicomponent and Domino Reactions

Fe₃O₄@SiO₂-CeCl₃ catalyzed chemoselective synthesis of functionalized 3-substituted-1,5-benzodiazepines via one-pot multicomponent and domino reactions has been developed. During the one-pot synthesis process, one new cycle and four new bonds (one C–C, two C–N and one C=C) were constructed by the nucleophilic addition and eliminate reaction (dehydration etc.) process, intramolecular proton transfer and cyclization process. The major advantages of the present method are good to excellent yields, shorter reaction time, simple experimental procedure, easy work up, mild reaction conditions, recyclability of the catalyst and ability to tolerate a variety of functional groups which gives economical as well as ecological rewards.     

Synthesis of 4,6-diarylpyrimidin-2(1H)-one derivatives from benzyl halides and (1-bromoethyl)benzene under solvent-free conditions

A facile synthesis of a series of pyrimidinone derivatives from the reaction of benzyl halides, (1-bromoethyl)benzene and urea in the presence of pyridine N-oxide (PNO) under solvent-free conditions is described. This transformation presumeably occurs via oxidation/cross-aldol condensation/Michael addition/intra molecular cyclization, domino sequence, involving the formation of one C–C bond and two C–N bonds in a single step.     

An electron localization function and catastrophe theory analysis on the molecular mechanism of gas-phase identity SN2 reactions

A set of four reactions, XCH₃+X^? (X=F, Cl, Br) and ClSiH₃+Cl^?, is investigated by means of the joint use of the electron localization function (ELF) and catastrophe theory (CT) analysis in order to obtain new insights into the bond breaking/forming processes for identity S_N2 gas-phase reactions. Using DFT calculations at the OLYP/6-311++G(d,p) level, the effect of nucleophile (F, Cl, and Br anions) and the role of reacting centers (C or Si) on the reaction mechanisms are investigated. The charge-shift character of carbon–halogen bonds is studied by determination of the weights of the Lewis resonance structures. In all S_N2 reactions at the carbon atom, there is a progressive reduction on the covalent character of the C–X bond from the reactant complex (0.41, 0.57, 0.58 for F, Cl, and Br, respectively) until the bond-breaking process, occurring before the transition structure is reached. On the other hand, the Si–Cl bond maintains its degree of covalent character (0.51) from the isolated fragments to the formation of a stable transition complex, presenting two silicon–chlorine charge-shifted bonds. The analysis of the ELF topology along the reaction path reveals that all reactions proceed via the same turning points of fold-type but the order is inverted for reactions taking place at C or Si atoms.     

Cu(I)-catalyzed cascade intramolecular cyclization of 2-propynol phenyl azides and diarylphosphine oxides for the synthesis of bisphosphorylated indole derivatives

The [Cu(OTf)]₂·C₆H₆ catalyzed cascade intermolecular addition–intramolecular cyclization reaction of easily prepared 2-propynol phenyl azides and diarylphosphine oxides was developed. This novel reaction leads to simultaneous formation of one C–N and two C–P bonds in a single step to give bisphosphorylated indole derivatives under mild conditions in moderate to good yields.     

[4 + 2] Heterocyclization for Efficient Formation of Substituted Quinoxalines through Carbon–Oxygen Bonds Cleavage

A new domino strategy for efficient synthesis of highly functionalized quinoxaline derivatives via [4 + 2] heterocyclization involving ring‐opening of oxirane process has been developed. The reaction promoted by Cs₂CO₃ was easy to perform in a simple operation from common and inexpensive starting materials. The bisfunctionalization of quinoxaline framework including C2 benzylation and C3 arylation was readily achieved in domino fashion that involved the cleavage of three C–O bonds of 1,3‐diaryl‐2,3‐epoxypropan‐1‐one.     

DFT study on the mechanism of Pd(OAc)<Subscript>2</Subscript>-catalyzed hydrothiolation of alkenes bearing heteroatoms with benzenethiol

The work reports the theoretical investigation of the mechanism and regioselectivity of the Pd(OAc)₂-catalyzed hydrothiolation of heteroatom-substituted alkenes with benzenethiol leading to Markovnikov-type product. The reaction process includes: (1) activation of the S–H bond for benzenethiol by the catalyst Pd(OAc)₂; (2) migratory insertion of the alkenes bearing heteroatoms into the Pd–S bond; (3) AcOH molecule attacks Pd–C bonds to give the product and release the catalyst. In addition, the computed results shown that Pd(OAc)₂-catalyzed hydrothiolation take place by two possible channels and get anti-Markovnikov-type or Markovnikov-type species. The Markovnikov-type reaction channel is more favored with the energy barriers of 21.9–25.6 versus 28.5–31.2 kcal/mol for the anti-Markovnikov-type pathway. The theoretical results and the experimental observations of Tamai and co-workers are consistent. This reaction would proceed in mild conditions and afford the Markovnikov-type products in high yields and regioselectivity.     

A DFT Study on the Mechanism of Rh2II,II‐Catalyzed Intramolecular Amidation of Carbamates

The potential‐energy surfaces of the reactions of dirhodium tetracarboxylate (Rh₂^II,II) catalyzed nitrene (NR) insertion into C H bonds were examined by a DFT computational study. A pure Becke exchange functional (B88) rather than a hybrid exchange functional (B3, BHandH) was found to be appropriate for the calculation of the energy difference between the singlet and triplet Rh₂^II,II–NH nitrene species. Rh₂^II,II–NR¹ (R¹=(S)‐2‐methyl‐1‐butylformyl) is thermodynamically more favorable with a free energy lower than that of Rh₂^II,II–N(PhI)R¹. The singlet and triplet states of Rh₂^II,II–NR¹ have similar stability. Singlet Rh₂^II,II–NR¹ undergoes a concerted NR insertion into the C H bond with simultaneous formation of the N H and N C bonds during C H bond cleavage; triplet Rh₂^II,II–NR¹ undergoes H atom abstraction to produce a diradical, followed by subsequent bond formation by diradical recombination. The singlet pathway is favored over the triplet in the context of the free energy of activation and leads to the retention of the chirality of the C atom in the NR insertion product. The reactivities of the C H bonds toward the nitrene‐insertion reaction follow the order tertiary>secondary>primary. Relative reaction rates were calculated for the six reaction pathways examined in this work.     

The thermal characteristics of potassium oxalato lanthanates: K3LnOx3 · n H2O (Ln=La−Tb) and K8Ln2Ox7 · 14 H2O (Ln=Tb−Yb,Y)

The title compounds were studied by TG, DTA, DSC, IR and absorption spectroscopy. The complexes go through dehydration (70–200°C), an irreversible exothermic process (in air or N₂ atmosphere, 250–300°C) and decomposition to a mixture of oxides and carbonates (385–700°C). The exothermic process occurs without weight loss and corresponding heats of reaction fall in the range 0–26 kJ/mol. The absorption spectrum of the Nd complex in the range 5000–6000 Å was employed to monitor perturbations in the coordination sphere of Nd³⁺ arising from the exothermic process. Involvement of the Nd³⁺ cation is implied and the heats of reaction show a close relationship to the radii of Ln³⁺. The interpretation of these data was made with the aid of valuable structural information obtained previously.     

Aluminiumhydrazide. Bildung eines dimeren Di(tert‐butyl)aluminiumhydrazids mit viergliedrigem Al2N2‐Heterozyklus und Umsetzung eines Dialkylaluminiumchlorids mit Dilithium‐bis(trimethylsilyl)hydrazid

Aluminium Hydrazides – Formation of a Dimeric Di( tert ‐butyl)aluminium Hydrazide Containing a Four‐Membered Al₂N₂ Heterocycle and Reaction of Dialkylaluminium Chloride with Dilithium Bis(trimethylsilyl)hydrazide The reaction of di(tert‐butyl)aluminium chloride with tert‐butylhydrazine yielded an adduct ( 1 ) which was isolated in a pure form and characterized by crystal structure determination. 1 reacted with n‐butyllithium by deprotonation and salt elimination to give the corresponding di(tert‐butyl)aluminium hydrazide ( 2 ), which is a dimer in solution and in the solid state and possesses a four‐membered Al₂N₂ heterocycle with two exocyclic N–N bonds. The structure of 2 differs from that of other di(tert‐butyl)aluminium hydrazides which have four‐ or five‐membered heterocycles. Treatment of impure samples of 1 with n‐butyllithium yielded by the cleavage of the N–N bonds a mixture of several unknown products, from which the dimeric, centrosymmetric aluminium amide [(Me₃C)₂AlN(H)CMe₃]₂ ( 3 ) was isolated. A similar product ( 4 ) was obtained in a low yield by the reaction of (Me₃SiCH₂)₂AlCl with the dilithium hydrazide Li₂N₂(SiMe₃)₂. An intact N–N bond was neither found in the second product isolated from this reaction. Instead a tricyclic compound was formed by C–H activation which has two five‐membered AlNSiC₂ heterocycles bridged by Al–N bonds.     

Catalytic and stereoselective iodination of prochiral C–H bonds

Oxazolines were employed as cyclic chiral directing groups for stereoselective C–H activation. Oxazoline-directed cleavage of the β-C–H bonds followed by reaction with I₂ gave a wide range of iodinated products. A large range of functional groups are tolerated. PdI₂ was isolated in the reaction and found to be converted to Pd(OAc)₂ upon treatment with a combination of I₂ and PhI(OAc)₂ in situ to achieve catalytic turnover. Diastereoselective iodination of prochiral C–H bonds were also investigated.     

Conversion of Triple Bonds into Single Bonds in a Domino Carbopalladation with Norbornene

A domino carbopalladation reaction of haloalkynes is presented. Remarkably, the four‐time carbopalladation process converts the carbon‐carbon triple bonds of haloalkynes stepwise into carbon–carbon double bonds, and finally to carbon‐carbon single bonds. Features of this reaction are that the carbon‐carbon double bonds of stable vinyl palladium intermediates are transformed into carbon‐carbon single bonds with the generation of unstable alkyl palladium intermediates. The subsequently formed π‐allylpalladium species are independently trapped by N ‐tosylhydrazones, boronic acids, and B₂pin₂ in a highly diastereoselective manner, delivering the corresponding polycyclic and twisted products with a bicyclo[3.2.1]oct‐2‐en‐3‐yl)tricyclo[3.2.1.0^2,4]octane core skeleton in moderate to good yields via C−C and C−B bond formations. Significantly, the dual roles of norbornenes, ring construction and ring expansion, and the identification of electron‐rich tri(2‐furyl)phosphine as the ligand are found to be critical for the success of these transformations.     

Preparation, characterization and application of KNH2/Al2O3 and KF/Al2O3 as strong solid bases

This review describes the preparation, characterization and application of KNH₂ loaded on alumina and KF loaded on alumina. These strong solid bases catalyze a variety of organic reactions in a very selective manner. The reactions include isomerizations of alkenes and alkynes, dimerization of alkynes, Tishchenko reaction, and the reaction of silanes to form of Si–C, Si–N and Si–O bonds.     

Thiozonation and thiozonolysis of triatomic sulfur (S<Subscript>3</Subscript>) on the C<Subscript>70</Subscript> fullerene: a DFT study

Density functional theory calculations have been carried out to investigate the [2?+?x] x?=?1, 2, and 3 cycloaddition reactions (paths A, B, and C) of triatomic sulfur (S₃) with the C₇₀ fullerene in terms of geometry, energies, and electronic structures. The thiozonation (S₃) on the hexagon–hexagon and hexagon–pentagon bonds of the C₇₀ fullerene through 1,3-dipolar reaction, i.e., [2?+?3] cycloaddition, is generally exothermic, while through the chelotrope additions, i.e., [2?+?1] cycloaddition, are endothermic. The results indicate that the 1,3-dipolar cycloaddition is the most preferable path. Having more negative values of reaction energies E_r together with the lower barrier heights, thiozonation of the hexagon–hexagon bonds is thermodynamically and kinetically more favorable than hexagon–pentagon ones. Moreover, the addition of thiozone to the hexagon–hexagon bonds near the pole area of the C₇₀ leads to more negative reaction energies. Therefore, it is established that the arrangement and position of C=C bonds play an important role in the thiozonation of C₇₀ fullerene. Thiozonolysis of triatomic sulfur (S₃) indicates that S–S bond cleavage has not occurred, instead a sulfur bridge over a C–C bond or a four-membered ring of 1,2-dithietane-1-sulfide is preferred to be formed.     

Direct Phenolysis Reactions of Unactivated Amides into Phenolic Esters Promoted by a Heterogeneous CeO2 Catalyst

The direct catalytic esterification of amides that leads to the construction of C−O bonds through the cleavage of amide C−N bonds is a highly attractive strategy in organic synthesis. While aliphatic and aromatic alcohols can be readily used for the alcoholysis of activated and unactivated amides, the introduction of phenols is more challenging due to their lower nucleophilicity in the phenolysis of unactivated amides. Herein, we demonstrate that phenols can be used for the phenolysis of unactivated amides into the corresponding phenolic esters using a simple heterogenous catalytic system based on CeO₂ under additive-free reaction conditions. The method tolerates a broad variety of functional groups (>50 examples) in the substrates. Results of kinetic studies afforded mechanistic insights into the principles governing this reaction, suggesting that the cooperative effects of the acid–base functions of catalysts would be of paramount importance for the efficient progression of the C−N bond breaking process, and consequently, CeO₂ showed the best catalytic performance among the catalysts explored.     

Tris(2-methoxy-5-bromophenyl)antimony bis(2-nitrobenzoate): Synthesis and specific features of the structure

Tris(5-bromo-2-methoxyphenyl)antimony bis(2-nitrobenzoate) (I) is synthesized by the reaction of tris(5-bromo-2-methoxyphenyl)antimony with 2-nitrobenzoic acid in the presence of hydrogen peroxide (mole ratio 1: 2: 1). According to the X-ray diffraction data, the antimony atom has distorted trigonal bipyramidal coordination. The axial angle OSbO is 177.92(11)°, equatorial bonds CSbC are 109.23(16)°–128.31(16)°, and the Sb-O and Sb-C bond lengths are 2.095(3)–2.125(3) and 2.098(4)–2.113(4) Å, respectively. A specific feature of the structure of complex I is the presence of intramolecular contacts Sb...O(CH₃) (2.992–3.175 Å along with the interactions Sb...O=C (3.039–3.117 Å). The structural organization in crystal is due to weak hydrogen bonds N-O...H-C, C=O...H-C, C-Br...H-C.     

Ein neuartiges Diorganylzinn(IV)-Komplexkation als Gastspezies in einer ionischen Harnstoff-Einschlußverbindung: Bildung und Struktur von [trans-Me2Sn{OC(NH2)2}4]2+ · 2 (MeSO2)2N7 · 6 (NH2)2CO

Polysulfonylamines. CVIII. A Novel Diorganyltin(IV) Complex Cation as Guest Species in an Ionic Urea Inclusion Compound: Formation and Structure of [ trans -Me₂Sn{OC(NH₂)₂}₄]²⁺ · 2 (MeSO₂)₂N⁷ · 6 (NH₂)₂CO The title compound (triclinic, space group P 1, Z = 1, X-ray analysis at –130 °C) was fortuitously obtained during an attempt to complex the known dimeric hydroxide [Me₂Sn(A)(μ-OH)]₂, where A⁷ = (MeSO₂)₂N⁷, with four equivalents of urea. The trans-octahedral and crystallographically centrosymmetric [Me₂Sn(urea)₄]²⁺ cation (Sn–O 221.6 and 223.7 pm, cis-angles in the range 90 ± 1.5°) is the first structurally authenticated [R₂Sn(L)₄]²⁺ complex featuring a urea-type ligand L. In the crystal, these cations are sandwiched between and hydrogen-bonded to puckered layers corresponding to the [011] family of planes. Each layer is constructed from rows of A⁷ anions, which extend parallel to the x axis and are alternatingly cross-linked by a planar zig-zag tape of urea molecules or by a pair of inversion-related urea zig-zag tapes displaying a non-planar roof profile. The structure contains 23 crystallographically independent hydrogen bonds N–H…O/N, comprising two intracationic N–H…O bonds, two and four N–H…O bonds leading to the two respective types of urea tapes, eight N–H…O bonds and one N–H…N⁷ bond connecting the urea tapes to the electronegative atoms of the anions, and six N–H…O interactions between the ligands of the complex guest cation and C=O or S=O acceptors within the layers of the host lattice. The anion A⁷ accepts a total of twelve H bonds and adopts a previously unreported conformation.     

Synthesis and Characterization of New Schiff Bases 2-(2-(2-(Aryl)Methyleneamino)Phenylthio) Ethylthio)-N-((aryl)Methylene)Benzeneamine

A series of Schiff bases containing four to six coordination sites N₂S₂ X₂(X = O,N) 2-(2-(2-(aryl)methyleneamino)phenylthio)ethylthio)-N-((aryl)methylene)benzeneamine (2c–f) were prepared from the reaction of 1,2-di(2-aminophenylthio)ethane (1) with aromatic aldehydes. All compounds were characterized by means IR, mass, ¹H and ¹³C NMR spectroscopy, and elemental analysis, and in the case of 2b with a single crystal X-ray diffraction. The X-ray crystal structure of 2b showed that the resonance occurs between aromatic rings, through the C=N bonds of the molecule.

Supplemental materials are available for this article. Go to the publisher's online edition of Phosphorus, Sulfur, and Silicon and the Related Elements to view the free supplemental file.     

A Light/Ketone/Copper System for Carboxylation of Allylic C−H Bonds of Alkenes with CO2

A photo‐induced carboxylation reaction of allylic C?H bonds of simple alkenes with CO₂ is prompted by means of a ketone and a copper complex. The unique carboxylation reaction proceeds through a sequence of an endergonic photoreaction of ketones with alkenes forming homoallyl alcohol intermediates and a thermal copper‐catalyzed allyl transfer reaction from the homoallyl alcohols to CO₂ through C?C bond cleavage.     

Supramolecular architecture built of Co(II) and a tripodal ligand containing 1-D water tapes with (H2O)16 cluster units

The reaction of Co(NO₃)₂?·?6H₂O with a tripodal ligand leads to a new complex {[Co(L)]?·?2NO₃?·?8H₂O} (1) confirmed by single-crystal X-ray diffraction, infrared spectroscopy, and elemental analysis. The particular interest of 1 is in the formation of a 1-D water tape consisting of (H₂O)₁₆ cluster units, the neighboring water tapes are connected by free nitrate anions via hydrogen bonds into a 2-D guest layer. These guest layers are alternately packed face-to-face with the 2-D host layers along the a-axis to form a 3-D supramolecular architecture. There exist C–H?···?N and C–H?···?O weak hydrogen bonds between the guest layer and host layer. These weak hydrogen bonds and water–nitrate, water–water hydrogen bonds are important for the stability of the overall structure.